US3131995A

US3131995A - Sodium perborate by the action of sodium metaborate on hydrogen peroxide

Info

Publication number: US3131995A
Application number: US807255A
Authority: US
Inventors: Gonze Max; Leblon Emile
Original assignee: Solvay SA
Current assignee: Solvay SA
Priority date: 1958-04-28
Filing date: 1959-04-17
Publication date: 1964-05-05
Anticipated expiration: 1981-05-05
Also published as: GB913688A; NL127291C; NL295197A; NL257777A; SE303479B; CH407964A; BE577317A; DE1243654B; CH405252A; NL122844C; FR84954E; BE634914A; US3109706A; DE1109152B; GB965091A; FR76697E; CH385804A; NL238433A; GB998649A; US3311446A

Description

CROSS REF United States Patent 3,131,995 Patented May 5, 1964 1 2 3 131 995 classified, for example, by passing through screens, having mesh openings comprised between 0.25 and 0.70 mm.

SODIUM PERBORATE BY THE ACTION OF SODIUM METABORATE ON HYDROGEN PEROXIDE process which is another object of the invention, products are easily obtained of which more than 60% are These products contain practically no fines and they may obviously be improved by screening. By modifying the Max Gone, Fol-angels, a Emile m 5 working conditions in the production it is possible to M l b bs i u B l Belgium, gssignofs produce products having larger or smaller particles while to Solvay & Cie., Brussels, Belgium, Belgian conserving the characteristics of the product, that is to company say: porous spherical particles of smooth or rough sur- Flled d 19599 807,255 face, a low apparent specific gravity and a great mobility.

Claims l ys lpllllmholl France P 1958 The apparent specific gravity by free flow of the new 9 Chumsproduct is comprised between 0.25 and 0.50 kg./c. dm.

The present invention relates to a completely new and ggj f gi z g P -g z a g gag i of improved form of solid sodium perborate which pree ave g e gg g fi/ e fiifi fiefi ififvifi iiii i531? e fise vi g iig aarent ens1t,anexceenmo tin e state fig particle sizes which can vary githin g wide average particle size it rs nevertheless possible to vary limits. the apparent specific gravity by increasing or decreasing The invention also concerns a new process of pro the internal empty spaees of the particles ducing this product The apparent specific gravity by free flow which is It is known that Sodium perborate has found at present mentioned m the present invention 1s determined by a es iumperoratespr uce musiayupo now:1 are rift entirely satisfactory. Tgihese are cratalline 32222 :5 g fiz g igsg i gggg g 31 3;? pro ucts avmg an apparent speci c gravity tween 0.65 and 0.75 kg./c. dm. (cubic decimeter). These prodss 3 i g 291 5 ucts have 1n general a satisfactory mobility but due to g gzi z gg m g e 22: :2 x i? d their apparent specific grav ty being more than twice I tal h h t e that of the other solid constituents of the washing powa opening 3 as a lame er 0 e ders and the size of the crystals being smaller than that height between the two bases bemg 58 and the useful of ifi g gfi fi f gg 'l li e ci' lih t i r l c up has a volume of 50 cc an in occur in e pac age uring an ng so at e rum perborate is displaced towards the bottom of the package ternall ig g y and fi t f g whereas the other constituents remain on top of it. As o e lame e ase o e upper 15 p ace afrisult, the commercial products show a complete lack g e i g :f gg igga f gg fi o omogenei y.

By of a it to M afia-slim est? risers; te m. heaps which have good moblllty properties but their apa; be te ted g h t paint specific gravity gg much g i l ii excess aid w liil eiil oidii't g confprez i z Ih ilpgz r l ese i umerous processes ave en recommene w c 40 permit sod um pesborate of low apparent specific gravity g gg s gg? ii zg r g sg ig g gi g z g; be btamede Thus pmduets havmg an apparent at the indicated distzihce and the obturator is bri eisl speclfic gravity to kgJc? have been Pbo ned in one stroke After the material has flowed tamed by effecting Wlth V1gOl'0US stirring the crystallizath rfl th d th tron of a saturated sodium perborate solution obtained :5 ig s ove owing e cup 15 remove W1 e by mixing hydrogen peroxide, borax and caustic soda and rapidlly removlijlllg the grystaltshformgd to :Void their is g g g sg g i i g fig gi g 8 g 9 23 223: growing arger. e pro ucts us 0 tame are very fine, have an insuflicient mobility and although light they ff t by g? 3 2 fi i tolthe e the are not suitable for the production of modern detergents. ma gf t Y e ume o e P It m to sodium in a .T g u s a in 1 tim o e e e s. y arithmetical average ofthe results is reported.

eir mo lity 1s prac lca y m A new form of crystallization of sodium perborate quamlty the produet through the orifice of the stem has now been discovered which permits all disadvantages of b a] th d hitherto encountered to be overcome and which is parb T gfi s g y an ogous to at escn ticularly capable of satisfying the diverse requirements simple g h is formed by a Pyrex glass 'l liz iiew product is characterized by the shape and 'gzp g s a F 5. i b g g aspect of the particles forming it, its apparent specific 'i g g a g i g gg i g z g 23 gravity and its mobility or free flow properties. the stem is 20 mm The P of Sodium perborate fofmm g the obiect The test consists introducing 250 g. of the product of the mvenuen are Porous spheres With a smooth or into the funnel and measuring the flow-time at the end rough e on account the Internal empty epaees of the stem. The products covered by the present inventhfise Particles 9 l? a relatively P tion are characterized by a flow-time not exceeding 10 of weight. Their size may vary within wide limits but seconds the granulometric classification of the crude crystallizah di pepboratgs f great, mobility and of an tron products is relatively narrow. According to the apparent; specific gravity comprised between 0.25 and 0.50

kg/c. dm. which form' the object of the present invention may be prepared from aqueous solutions of sodium metaborate, hydrogen peroxide and stabilizers by contacting sodium metaborate with hydrogen peroxide in the presence of at least one of the constituents of the stabilizer, keeping the reaction medium under continuous but not rough agitation and effecting the crystallization of sodium perborate at a temperature comprised between and 12 C., starting from a solution in which the relative supersaturation in perborate, expressed by the ratio between the weight of perborate virtually present in the solution and the weight of perborate normally soluble in water at 20 C., is comprised between 4 and 12.

A stabilizer is preferably used consisting of magnesium silicate which is produced in situ by reacting magnesium chloride or sulphate with sodium silicate. However, other stabilizers may be used, for example the reaction products of a tin stannate or halide with sulphuric, phosphoric or hydrofluoric acids; silicates of barium, of calcium, of strontium, etc.

According to an especially advantageous variant of the process the sodium metaborate solution is preferably introduced into the aqueous solution of hydrogen peroxide. The constituents of the stabilizer are dissolved in the aqueous solutions of the reagents, for example, magnesium, calcium, barium chloride or sulphate is dissolved in the aqueous solution of hydrogen peroxide, while the alkaline silicate is dissolved in the aqueous solution of sodium metaborate. The constituents of the stabilizer may, however, also be introduced in inverse order, that is to say sodium silicate into hydrogen peroxide, but in this case it is expedient to introduce the calcium, magnesium, barium etc. salts separately into the reactor, in order to prevent the formation of precipitates of hydroxides of these metals upon contact with the aqueous alkaline solution of sodium metaborate. When the alkaline earth metal chloride or sulphate is introduced into the aqueous solution of hydrogen peroxide, placed previously into the crystallization reactor, it is possible, if desired, first to introduce the sodium metaborate solution and to introduce sodium silicate only after the reagents have been mixed.

Aqueous solutions of hydrogen peroxide are used at a H 0 concentration of 25 to 250 g./kg. so that, after addition of the sodium metaborate solution, the supersaturation in sodium perborate as specified above is comprised between 4 and 12. The H O -concentrations mentioned above presuppose the use of metaborate solutions at a concentration close to saturation, that is to say of about 190 g./ kg. It is to be understood that the desired supersaturations are obtainable by using more highly concentrated hydrogen peroxide solutions together with more dilute metaborate solutions, but this mode of operation is essentially less economical.

When the reagents are introduced, in general at ambient temperature, the reaction mixture is brought to a temperature of between 0 and 12 C., preferably between 5 and C., and stirring is continued, but not roughly, until the crystallization is terminated. The precipitate thus formed is then filtered and dried.

The mixture of the reacting solutions is advantageously effected within about minutes. However, the introduction of the reagents may be effected more slowly, but too long an introduction period should be avoided if low apparent specific gravities are desired.

The time required for bringing the reaction medium to a temperature of below 12 C. has a relatively small influence on the physical properties of the product, but periods of more than about an hour should be avoided.

Stirring is continued throughout the operations, care being taken not to let it become rough. For this purpose, a stirrer (Ancre) is preferably used, to which a little helix may be attached. It has been observed that it is desirable for the liquid to be moved in parallel layers. .A peripheral stirring speed of 0.5 to 1.5 m./sec. may be maintained without essentially modifying the properties of the precipitated particles.

The quantities of reagents to be used are approximately stoichiometric quantities. A slight excess of one or the other reagent may be employed.

The sodium metaborate solution is in most cases prepared beforehead by the action of caustic soda on borax in an aqueous medium.

This method of operation permits certain impurities from the starting materials to be separated by filtration and contributes to obtain a sodium perborate of high stability. For certain special applications or if a lower stability is desired, the metaborate solution may be produced in the course of the operations, but by avoiding the presence of a momentary excess of caustic soda, which is unfavorable to the stability of the hydrogen peroxide used; for the preparation of the metaborate, a slight excess of caustic soda or borax may be used indifferently. However, an excess of caustic soda may give rise to inopportune precipitates by reaction with the alkaline earth metal salts which are in most cases employed as constituents of the stabilizers. A slight excess of borax increases the mechanical properties of the moist particles and this facilitates their handling before drying.

The following examples are given for the purpose of illustrating the process which is the object of the invention, and of making it better understood. These examples show the variable influence of the various conditions of the method of operation, but they are in no way limitative.

In all cases, the tests have been carried out in a beaker having a capacity of 3 liters which is placed in a thermostatic bath, fitted with an Ancre" stirrer of 120 mm. diameter and revolving at variable speed.

The constituents of the stabilizer are introduced in an aqueous solution or in the crystalline state.

(1) INFLUENCE OF THE STIRRING SPEED 98.4 g. of H 0 are placed in the beaker in the form of an aqueous solution at a concentration of 100 g. of H 0 per kg. of solution. 2.43 g. of MgCl bH O are dissolved therein. The mixture is stirred while introducing within minutes a mixture of 1003 -g. of a solution having a sodium metaborate concentration of 189 g./kg. and 8.2 g. of a sodium silicate solution of 36 B.

When the reagents are introduced, the temperature of the thermostatic bath is brought to +3 C. within 10 minutes corresponding to a temperature of +5 C. in the reaction medium. When the crystallization is terminated, the temperature which has risen to 8l2 C. is brought back to +5 C., the particles are filtered and dried.

The characteristics of the products thus obtained are given in Table 1 as a function of the stirring speed.

Table 1 Apparent Fluidity ol Classified specific the product product, Stirring speed, r.p.m. gravity, flow-time, 0.254).? mm.,

kg./c. dm. dry kgJkg. of

product It has been found that the stirring speed has only a slight influence on the apparent specific gravity so long as it does not become rough. The granulometry of the product is slightly improved, at low stirring speeds.

In contrast, if the test is repeated under the conditions indicated above, but effecting the stirring by means of a three-paddle stirrer revolving at a speed of 406 rpm, large crystals are obtained which are well formed but whose apparent specific gravity by flowing freely is 0.65 kg./c. dm.

(2) INFLUENCE OF THE PERIOD OF INTRODUCTION OF METABORATE The process is carried out under the same conditions as in the examples described above, the stirring speed being fixed at 106 r.p.m. and the period of introduction of the sodium metaborate solution being variable.

Table 2 Apparent Introduction period 01 specific Flnidity oi metaborate, min. gravity, product flowkg.[c. drn. time, dry

The specific gravity increases slightly with the increase of the introduction time of metaborate.

It is thus almost impossible to exceed essentially a period of introduction of 120 minutes under the conditions described above or else the apparent specific gravity will rise above 0.5 kg./c. dm.

It should be noted that if the reagents are kept together without lowering the temperature, crystallization still proceeds at 20 C. after a rather prolonged time, but the product thus obtained does not meet the conditions stipulated for the new product which is the object of this invention.

(3) INFLUENCE OF THE PROPORTIONS OF AL- KALINE EARTH METAL SALT AND SODIUM SILICATE.

Working conditions:

Concentration of the aqueous H O, solu- These tests show that by increasing the ratio of silicate/alkaline earth metal salt, it is possible to reduce the apparent specific gravity.

All products thus obtained are porous spheres the majority of which are hollow.

(4) INFLUENCE OF SUPERSATURATION IN SODIUM PERBORATE Into the apparatus described above, there is introduced 1 kg. of hydrogen peroxide solution containing varying quantities of H and a quantity of MgCl .6H O corresponding to 24.7 g./kg. of H 0; employed. To this solution there are added per kg. of H 0, used within 15 minutes, 10.2 kg. of a solution at a sodium metaborate concentration of 189 g./kg. and 8.2 g. of sodium silicate 36 B. within 15 minutes. Stirring is continued at a speed of 106 rpm.

When the whole metaborate solution is introduced, the thermostatic bath is cooled to +3 C. within minutes. Stirring is continued, the liquid in the reactor being kept at a temperature of +5 C. After crystallization, the mixture which has become warm is brought back to +5 C. The product is filtered and the separated particles are dried.

Table 4 Classified 11,0, Con- Relative Apparent Fluidity, product, Test tent of superspecific flowtune 0.254)] No. solution, saturation gravity, dry mm., kg./

gJkg. kgJc. dm. kg. 01

product 1 The relative supersaturation is the ratio between the weight otsodium perborate virtually present, and the weight of perborate which is soluble in Water at 20 C.

The products obtained under the conditions of tests 3, 4 and 5 are porous spheres the majority of which are hollow. The product corresponding to test 1 consists of small cubes, whereas the products corresponding to tests 2 and 6 consist of macled crystals of the nature of crossed twins and of deformed spheres. The tests 1, 2 and 6 yield products which are not satisfactory in the fluidity test. supersaturation leading to a good product must thus be comprised between 4 and 12.

(5) INFLUENCE OF THE STABILIZER AND THE METHOD OF ITS INTRODUCTION (0) Test without stabilizer.When crystalization is effected in the complete absence of the essential elements of the stabilizer, products are obtained the physical prop erties of which are not satisfactory. If the cooling of the reaction medium to a temperature of about 5 C. is carried out immediately after the introduction of the reagent, crystals are obtained which are strongly agglomerated and unsatisfactory in the fluidity test.

If the reaction medium is kept at a low temperature during the introduction of the reagents, there are likewise obtained macled crystals and the apparent specific gravity exceeds 0.5 kg./c. dm.

(b) Order of introduction of the stabilizer constituents.The best results are obtained by introducing the alkaline earth metal halide or sulphate into the hydrogen peroxide solution and the sodium silicate into the sodium metaborate solution, as shown in the preceding examples.

However it is also possible to work in inverse order, that is to say to introduce the sodium silicate into hydrogen peroxide, and the alkaline earth metal compounds simultaneously with the metaborate.

Into the apparatus already described, there are introduced 8.2 g. of sodium silicate of 36 B. and 984 g. of a solution containing 100 g. of H 0 per kg. of solution.

To this solution there are added simultaneously but separately, within 15 minutes, 1003 g. of a solution containing 189 g. of NaBO /kg. and 50 g. of a solution containing 22.8 g. of MgCl /kg. or corresponding quantities of other alkaline earth metal compounds. When the introduction of these solutions is terminated, the thermostatic bath is cooled immediately and brought to a temperature of 3 C. within 10 minutes. After crystallization of the perborate, the solid product is separated from the mother liquor, then dried.

If desired, the mixture of the reagents may be efiected in the presence of only one of the essential elements of 7 the stabilizer, the other one being added thereafter, preferably before crystallization sets in.

In the 3 liter beaker are introduced 2.43 g. of

Apparent specific gravity 0.39 kg./c. dm. Fluidity, flow-time 5 seconds.

Classified product, 0.25-0.7 mm. 0.69 kg./kg. of product.

(6) ORDER OF INTRODUCTION OF METABORATE SOLUTION According to a preferred variant of the process, the sodium metaborate solution has been introduced in all the preceding examples, into the hydrogen peroxide solution. This order may however be reversed as will be shown in the following example.

Into the crystallization apparatus are introduced 1003 g. of a metaborate solution at a concentration of 189 g./kg. and then 8.2 g. of sodium silicate 36 B. To this are added with stirring (stirring speed 106 r.p.m.) within minutes 984 g. of a hydrogen peroxide solution at a H O, concentration of 100 g./kg. containing 2.45 g. of MgCl,.6H O per kg.

When the introduction of this solution is terminated, the thermostatic bath is cooled to +3 C. within 10 minutes.

The process is then carried out as in the preceding examples.

The product thus obtained consists of spherical agglomerates and is characterized by the following properties:

Apparent specific gravity -..kg./c. dm.-- 0.44 Fluidity, flow-time seconds 5 Classified product, 0.7-0.25 mm kg./kg.- 0.54

In all the tests described above quantities of hydrogen peroxide are used which essentially correspond to an excess of 1% with regard to the stoichiometric quantities, and the metaborate employed has been produced from stoichiometric quantities of borax and caustic soda. However, it has been found that by working with sodium metaborate containing an excess of borax of the order of 5 to 10 g./kg. of solution, it is possible to obtain the same products while improving the mechanical resistance of the moist particles.

Moreover, the sodium metaborate solution used for carrying out all the tests, has been prepared beforehand by the action of caustic soda on borax, the solution thus obtained being filtered, in order to eliminate the precipitated insoluble impurities.

It has been found that the preparation of sodium metaborate can be efiected immediately before or even during the reaction with hydrogen peroxide provided that in the crystallization reactor, the caustic soda is not present in a substantial excess which would be detrimental to the stability of the hydrogen peroxide employed.

We claim:

1. An industrial product, sodium perborate in the form of porous spherical particles the apparent specific gravity of which, measured by flowing freely, is comprised between 0.25 and 0.50 kg./cubic decimeter and whose mobility, expressed by the flow-time of a weight of 250 g. through the orifice of a short stem analysis funnel of 180 mm. diameter, does not exceed 10 seconds.

2. An industrial product as defined in claim 1 wherein the majority of the particles have a size comprised between 0.25 and 0.7 mm.

3. Process for the manufacture of sodium perborate of great mobility and an apparent specific gravity between 0.25 and 0.50 kg./cubic decimeter, by the action of sodium metaborate on hydrogen peroxide in the presence of a. stabilizer for said sodium perborate, said stabilizer being an alkaline-earth metal silicate, comprising the steps of contacting a sodium metaborate solution with a hydrogen peroxide solution in the presence of at least one of the constituents of the stabilizer at ambient temperature to produce a supersaturated solution in which the relative supersaturation in perborate expressed by the ratio between the weight of perborate virtually present and the weight of perborate which would normally be soluble in water at 20 C. is comprised between 4 and 12, stirring the reaction medium continuously but not roughly to displace the liquid medium continuously in parallel layers, and effecting the crystallization of the perborate by cooling the reaction medium to a temperature between 0 C. and 12 C. within a short time not exceeding one hour.

4. Process according to claim 3 wherein the stabilizer is magnesium silicate formed in situ from magnesium chloride and sodium silicate.

5. Process according to claim 3 wherein an alkaline earth metal salt is dissolved in an aqueous hydrogen peroxide solution containing at least 25 g. of H 0 per kg. of solution and into this solution there is introduced a sodium metaborate solution at a concentration close to saturation and containing sodium silicate.

6. Process according to claim 3 wherein the metaborate solution is introduced into the hydrogen peroxide solution within less than minutes.

7. Process according to claim 3 wherein the reaction mixture is stirred continuously but not roughly by means of an agitator revolving at a peripheral speed of 0.5 to 1.5 m./sec.

8. Process according to claim 3 wherein the sodium metaborate solution is formed during the production of the perborate by the action of caustic soda on borax in an aqueous medium.

9. Process for the manufacture of sodium perborate of great mobility and an apparent specific gravity between 0.25 and 0.50 kg./cubie decimeter, by the action of sodium metaborate on hydrogen peroxide in the presence of a stabilizer for said sodium perborate, said stabilizer being an alkaline-earth metal silicate, comprising the steps of contacting a sodium metaborate solution with a hydrogen peroxide solution in the presence of at least one of the constituents of the stabilizer at ambient temperature to produce a supersaturated solution in which the relative supersaturation in perborate expressed by the ratio between the weight of perborate virtually present and'the weight of perborate which would normally be soluble in water at 20 C. is comprised between 4 and 12, stirring the reaction medium continuously but not roughly to displace the liquid medium continuously in parallel layers, and effecting the crystallization of the perborate by cooling the reaction medium to a temperature of about 5 C. within a very short time of the order of 10 to 15 minutes.

References Cited in the file of this patent UNITED STATES PATENTS 2,937,998 Habernickel May 24, 1960 FOREIGN PATENTS 761,371 Great Britain Nov. 14, 1956 211,626v Australia Oct. 24, 1957

Claims

3. PROCESS FOR THE MANUFACTURE OF SODIUM PERBORATE OF GREAT MOBILITY AND AN APPARENT SPECIFIC GRAVITY BETWEEN 0.25 AND 0.50 KG./CUBIC DECIMETER, BY THE ACTION OF SODIUM METABORATE ON HYDROGEN PEROXIDE IN THE PRESENCE OF A STABILIZER FOR SAID SODIUM PERBORATE, SAID STABILIZER BEING AN ALKALINE-EARTH METAL SILICATE, COMPRISING THE STEPS OF CONTACTING A SODIUM METABORATE SOLUTION WITH A HYDROGEN PEROXIDE SOLUTION IN THE PRESENCE OF AT LEAST ONE OF THE CONSTITUENTS OF THE STABILIZER AT AMBIENT TEMPERATURE TO PRODUCE A SUPERSATURATED SOLUTION IN WHICH THE RELATIVE SUPERSATURATION IN PERBORATE EXPRESSED BY THE RATIO BETWEEN THE WEIGHT OF PERBORATE VIRTUALLY PRESENT AND THE WEIGHT OF PERBORATE WHICH WOULD NORMALLY BE SOLUBLE IN WATER AT 20*C. IS COMPRISED BETWEEN 4 AND 12, STIRRING THE REACTION MEDIUM CONTINOUSLY BUT NOT ROUGHLY TO DISPLACE THE LIQUID MEDIUM CONTINOUSLY IN PARALLEL LAYERS, AND EFFECTING THE CRYSTALLIZATION OF THE PERBORATE BY COOLING THE REACTION MEDIUM TO A TEMPERATURE BETWEEN 0.C. AND 12*C. WITHIN A SHORT TIME NOT EXCEEDING ONE HOUR.